AU666202B2

AU666202B2 - Pixel intensity modulator

Info

Publication number: AU666202B2
Application number: AU42408/93A
Authority: AU
Inventors: Andrei Szilagyi; Gregory Um
Original assignee: Aura Systems Inc
Current assignee: Aura Systems Inc
Priority date: 1992-05-18
Filing date: 1993-05-07
Publication date: 1996-02-01
Anticipated expiration: 2013-05-07
Also published as: WO1993023959A1; AU4240893A; EP0594829A4; JPH07508387A; CA2113645A1; CA2113645C; US5260798A; EP0594829A1

Description

6PI DATE 13/12/93 APPLN. ID 42408/93 II III ii IJII ll11 AOJP DATE 24/02/94 PCT NUMBER PCT/US93/04377 ill lllllillll AU9342408 (51) International Patent Classification 5 International Publication Number: WO 93/23959 HO4N 9/31, 5/74 Al (43) International Publication Date: 25 November 1993 (25.11.93) (21) International Application Number: PCT/US93/04377 (81) Designated States: AU, CA, JP, KR, European patent (AT, BE, CH, DE, DK, ES, FR, GB, GR, IE, IT, LU, MC, (22) International Filing Date: 7 May 1993 (07.05.93) NL, PT, SE).

Priority data: Published 07/885,727 18 May 1992 (18.05.92) US With international search report.

Before the expiration of the time limit for amending the claims and to be republished in the event of the receipt of (71) Applicant: AURA SYSTEMS, INC. [US/US]; 2335 Alaska amendments.

Avenue, El Segundo, CA 90245 (US).

(72) Inventors: UM, Gregory 23006 Carlow Road, Torrance, CA 90505 SZILAGYI, Andrei 30917 Ganado Drive, Rancho Palos Verdes, CA 90274 (US).

(74) Agents: CASCIO, Anthony, T. et al.; Aura Systems, Inc., 2335 Alaska Avenue, El Segundo, CA 90245 (US).

666202 (54)Title: PIXEL INTENSITY MODULATOR KI I 34 -S14 S36 40 16 26 22 Abstract 24 An apparatus to modulate the intensity of a pixel displayed on a screen (24) focuses optical energy from a broadbrand source (12) onto a reflective first face of a planar member The first face is disposed in said first propagation path (34) at a selected angle thereto to direct optical energy along a second propagation path A planar mirror (20) is disposed in the second propagation path The plane of the mirror is actuatable to orientate the mirror within a range of angles to said second propagation path (40) to focus optical energy reflected from the first face onto the mirror WO 93/23959 PCT/US93/04377 -1- PIXEL INTENSITY MODULATOR FIELD OF THE INVENTION The present application is continuation-in-part of io commonly owned, co- ing application Serial No.

07/448,748, file ecember 11, 1989, which is a continuatio -part of Serial No. 07/429,987, filed November 1, each of which is incorporated herein by reference.

FIELD OF THE INVENTION The present invention relates generally to optical projection systems and more particularly to a novel display projection system using an actuated mirror array to effect modulation of pixel intensity.

BACKGROUND OF THE INVENTION Actuated mirror arrays are useful for one component in the modulation of light intensity wherein the beam reflected from each mirror is modulated by, the flux 3 f such beam Rat-, i>0D&, 4 fo 1+ DaJ qk(4d d/ i-7 GdlInpassing through a slit aperture, as disclosed in Se-r4aFNe 7 r- iN.r-- P, 4 As described therein, the flux is controlled by the orientation of the mirror relative to the aperture. A piezoelectric actuator has been disclosed for actuating each mirror in response to an electrical signal WO 93/23959) PCT/US93/04377 -2applied to each actuator. The electrical signal is commensurate with the degree of modulation desired. The U 13 control circuitry for the actuators has been dec na N a.fl7o'1 which is incorporated herein by reference.

Several examples of piezoelectric actuators and mirror arrays constructed therefrom are disclosed inrrIT SUMMARY OF THE INVENTION According to the present invention, an apparatus to modulate the intensity of a pixel displayed on a screen focuses optical energy from a broadband source onto a reflective first face of a planar member. The first face is disposed in said first propagation path at a selected angle thereto to direct optical energy along a second propagation path. A planar mirror is disposed in the second propagation path. The plane of the mirror is actuatable to orientate the mirror within a range of angles to said second propagation path between a first angle limit and a second angle limit. A second focusing lens disposed in the second propagation path to focus optical energy reflected from the first face onto the mirror. The mirror when at the first angle limit reflects optical energy along the second propagation path to the first face and when at the second angle limit reflects optical energy along a third propagation path adjacent an edge of the planar member and external thereto so that flux of optical energy along the third propagation path is a function of the present orientation of the mirror between the first angle limit and the second angle limit. The screen is disposed in the third propagation path wherein the flux of optical energy along the third propagation path when focused on the screen determines the intensity of the pixel.

WO 93/23959 PC'T/US93/04377 -3- In another aspect oi the present invention, a novel actuator fabricated from either piezoelectric or electrostrictive material is described.

These and other objects, advantages and features of the present invention will become readily apparent to those skilled in the art from a study of the following Description of an Exemplary Preferred Embodiment when read in conjunction lo with the attached Drawing and appended Claims.

BRIEF DESCRIPTION OF THE DRAWING Figure 1 is a schematic view of a novel display projection system constructed according to the principles of the present invention; Figure 2A is an enlarged schematic of a portion of Figure 1; Figure 2B is a view similar to Figure 2A showing an alternative embodiment thereof; and Figure 3 is a cross-sectional view of one mirror actuator of Figure 1.

DESCRIPTION OF AN EXEMPLARY PREFERRED EMBODIMENT Referring now to the Figure 1 and Figure 2A, there is shown a display projection system 10 constructed according to the principles of the present invention. The scene projector WO 93/23959 PCT/US93/04377 -4includes a source 12 of optical energy, a first focusing lens 14, a planar member 16, a second focusing lens 18, an actuated mirror array 20, a collimating lens 22 and a screen 24. The system 10 may also include a scanning mirror 26.

The source 12 may include any broadband source 28 of energy. The energy may also be in the spectrum long wave infrared (LWIR) to ultraviolet The source may also include a collimating lens 30 and a filter 32. The collimating len6 30 collimates the energy from the source 28 and directs it to the plane of the filter 32. The filter 32 is useful for filtering unwanted wavelengths from the optical energy. For example for a video projector, the filter 32 may remove infrared (heat) and ultraviolet whereas if an infrared scene projector is desired, the filter 32 will remove the visible spectrum.

The first focusing lens 14 is disposed intermediate the planar member 16 and the source 12. The first focusing lens 14 focuses the optical energy emitted from the source 12 along a first propagation path 34 onto a first face 36 of the planar member 16. The point at which the energy is focused is adjacent an edge 38 of the planar member, as best seen in Figure 1. The first face 36 of the planar member 16 is optically reflective.

The planar member 16 is disposed at a selected angle with respect to the first propagation path 34 so that optical energy is reflected from the first face along a second propagation path 40. The optical energy along the second propagation path 40 fans out until it is incident on the second focusing lens 18. The second lens 18 collimates the optical WO 93/23959 PCTUS93/04377 energy along the second path. The collimated energy is then incident on the actuated mirror array With particular reference to Figure 2A, each mirror 2 0ij of the mirror array 20 is disposed in the second propagation path 40. The orientation of each mirror 2 0ij determines the intensity of a respective pixel to be displayed at the screen 24. For example, if the plane of a particular mirror 2 0ij is normal to the second propagation path 40, the optical energy io reflected therefrom will return to the planar member 16 along the second propagation path 40. More particularly, the second lens 18 will focus the energy reflected from the mirror 2 0ij surface back to its original point of incidence on the reflective first face 36. This orientation of the mirror 2 0ij defines a first angle limit.

However, if the plane of the mirror 20ij is offset from the normal to the second propagation path 40, the reflected optical energy will be along a path diverging from the second propagation path 40. This divergent energy is focused by the second lens 18 at a point offset from the original point of incidence on the reflective first face 36 so that some energy is not blocked by the planar member 16 but continues pass the edge 38. Accordingly, an increasing offset of the plane of the mirror 20ij will decrease the flux of the optical energy returning to the original point of incidence on the first face 36 and thereby increase the flux of optical energy going past the edge 38.

When the mirror 2 0ij is at its full actuated position, defining a second angle limit, none of the reflected energy therefrom returns to the original point of incidence on the reflective face 36 and all of it passes the edge 38. This WO 93/23959 PCT/ US93/04377 -6energy propagates along a third propagation path 42.

Therefore, the present orientation of the mirror 2 0ij between the first angle limit and the second angle limit determines the flux energy along the third propagation path and hence the intensity of a pixel developed from the energy reflected from such mirror 2 0ij.

The collimating lens 22 is disposed in the third propagation path to eliminate the fan out of the energy along io the third propagation path 42 and collimate it for display on the screen 24. The screen 24 may either display the optical energy incident thereon or be an array of photodetector elements wherein each photodetector uses the optical energy incident thereon as information for the further development of a corresponding pixel. A scanning mirror 26 may be disposed between the collimating lens 22 and screen 24 for scanning a column (or row) of pixels if the mirror array 20 is a Mxl array, where M is the number of rows (or columns). If the mirror array 20 is a MxN array, the full array of pixels is displayed and scanning is not necessary.

Referring to Figure 2B, there is shown an alternate arrangement of the mirror array 20 and the planar member 16.

The optical energy along the first propagation path is first incident on the mirror 20ij. The orientation of the mirror 2 0ij at its first angle limit, normal to the first propagation path, will return the optical energy to the source. When the orientation of the mirror 20ij is at its second angle limit, the entire flux of the optical energy will be directed along the second propagation path 40 and reflected from the reflective face 36 as a full intensity pixel along the third propagation path 42. When the mirror 2 0ij is between the angle limits the amount of flux reaching the reflective face 36 is accordingly WO 93/23959 PC'I/US3/0437-/ -7controlled for intensity modulation according to the above described principles.

Referring to Figure 3, there is shown on embodiment of an actuator 50 for the mirror 2 0ij. The actuator 50 includes a first member 52 and a second member 54. Each member 52, 54 includes a first side surface 56, a second side surface 58, a top surface 60 and a bottom surface 62. The bottom surface 62 of each member 52, 54 is mounted to a substrate 64. The io mirror 20ij is mounted to the top surface 60 of each member 52,54.

The first side surface 56 of each member 52,54 are bonded face to face by a conductive epoxy which is electrically connected to electrically conductive metallization 66 along the bottom of the substrate 64 and within the via 68. The metallization 66 forms a common connection for all mirrors in the array 20. A metalization 70 is disposed on each second side surface 58 and isolated from each other metallization 70. The members 62,64 are formed from either piezoelectric or electrostrictive material.

Each member 62,64 has a polarization selected so that a voltage of a first polarity applied to its second side surface 58 causes the member 62,64 to contract between its top surface 60 and its bottom surface 62. The voltage when applied to the second side surface 58 the first member 62 causes the mirror 20ij to tilt toward the first member 62 due to its contraction and the dimensional constancy of the second member 64. Similarly, the voltage when app ed to the second side surface 58 of the second member 64 causes the mirror to tilt toward the second member 64 due to its contraction and the dimensional constancy of the first member 62.. The WO 93/239591 PCT/US93/04377 -8voltage is applied across the second side surface 58 through the metallization To obtain a greater degree of tilt, the voltage may be simultaneously applied to the second side surface 58 of each member 62,64 but of opposite polarity at each side surface 58.

This will cause one of the members 62,64 to contract and the other of the member 62,64 to expand. This arrangement requires that each member be piezoelectric since io electrostrictive only contracts independent of polarity.

Titling may also be accomplished with one of the members being replaced by a thick layer of metallization which acts as the common connection. The voltage applied to the opposite face of the remaining member will cause the contraction or expansion thereby causing the top surface to tilt since the metallization remains dimensionally constant.

There has been described hereinabove a novel display projection system which uses an actuated mirror array. Those skilled in the art may now make numerous uses of and departures from the above described embodiments without departing from the inventive concepts disclosed herein.

Accordingly, the present invention is to be defined solely by the scope of the following claims.

Claims

4. An apparatus as set forth in claim 3, further comprising a collimating lens disposed between said first face and said screen to focus energy propagating along said third propagation path on said screen. Apparatus to modulate the intensity of a pixel displayed on a screen substantially as described herein with reference to Figs. 1, 2A and 3, or Figs. 1, 2B aind 3 of the drawings. DATED this Twentieth Day of November 1995 Aura Systems, Inc. Patent Attorneys for the Applicant 10 SPRUSON FERGUSON o* it. i ,i-aiol i rn